WO1994028164A1

WO1994028164A1 - Biological sterelization indicator for use with or without test pack materials or devices

Info

Publication number: WO1994028164A1
Application number: PCT/US1994/005627
Authority: WO
Inventors: Lewis P. Woodson
Original assignee: Minnesota Mining And Manufacturing Company
Priority date: 1993-05-20
Filing date: 1994-05-19
Publication date: 1994-12-08
Also published as: CA2161685A1; AU676743B2; JP3558635B2; DE69415318D1; EP0699241B1; ES2125460T3; AU6953694A; EP0699241A1; JPH08510646A; DE69415318T2

Abstract

A biological indicator which utilizes immobilization to increase the thermostability of the biomaterial (e.g., microorganism or enzyme) contained within the indicator. Due to the increased thermostability of the biomaterial, the indicator can be utilized to monitor sterilization with or without conventional test pack materials or devices.

Description

BIOLOGICAL STERILIZATION INDICATOR FOR USE

WITH OR WITHOUT TEST PACK MATERIALS OR DEVICES

Field of Invention

The present invention relates to a biological indicator which utilizes immobilization to increase the thermostability of the biomaterial (e.g., microorganism or enzyme) contained within the indicator. The

biological indicator can be utilized to give a read-out of sterilization efficacy either with or without test pack materials or devices. Background of the Invention

Biological indicators used to determine the efficacy of sterilization are well known in the art. In conventional biological indicators, a test organism which is more resistant to the sterilization process employed than most organisms which would be present by natural contamination is coated on a carrier and subjected to a sterilization cycle along with the articles to be sterilized. After completion of the sterilization cycle, the carrier is incubated in nutrient medium to determine whether any of the test organisms survived the sterilization procedure.

Several procedures have been proposed to test the efficacy of sterilization equipment using biological indicators. The Association for the Advancement of Medical Instrumentation (AAMI) has published

recommendations for evaluating both ethylene oxide and steam sterilizers. For qualification testing of an ethylene oxide sterilizer, AAMI recommends placing a biological indicator into the barrel of a plastic syringe. A plastic airway, a length of latex tubing, and two of said syringes are placed in the center of a stack of folded surgical towels. The stack is then wrapped in a wrapping material. The resulting test pack is designed to challenge the parameters of

ethylene oxide sterilization.

The AAMI's recommendations for a test pack for use in steam gravity displacement and prevacuum sterilizers include using an appropriate biological indicator in a 14 to 16 towel test pack. The towels are folded and stacked. The biological indicator should be placed between the seventh and eighth towels in the geometric center of the pack.

Test packs containing biological indicators and other materials are intended to challenge all of the parameters necessary for evaluation of efficacy of ethylene oxide and steam sterilizers. One requirement of both types of AAMI test packs is to impede the flow of sterilant to the biological indicator to more closely simulate the rate of sterilization experienced by the load. Although effective for its intended purpose, the construction of an AAMI test pack for ethylene oxide and steam sterilization cycles is labor intensive and the resulting pack is bulky. In light of these limitations, several commercially available products address the need for a single pre-assembled and standardized composite sterilization test pack.

Exemplary products include the "1278 Attest™ EO Pack" and "1276 Attest™ Steam Pack", both commercially available from 3M, and those devices disclosed in U.S. Patent NOS. 4,739,881; 4,828,797; 4,839,291; 4,636,472; 4,918,003; and in European Patent Nos. 421,760;

419,282; and 255,229.

Summary of the Invention

The present invention provides, for the first time, a simple biological indicator device which can be used without towels, syringes or other bulky test pack materials and provides sterilization evaluations which are equivalent to or better than those of the prior art devices .

The present invention provides a biological indicator comprising

(a) an outer container having liquid impermeable walls, said container having at least one opening therein,

(b) contained within said outer container a

detectable amount of an immobilized

(1) viable test microorganism, or

(2 ) other source of active test enzyme known to be useful to monitor sterilization, which microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized microorganism or enzyme to survive or remain active following a sterilization cycle which is sublethal to test microorganisms contained in a test pack commonly used to monitor sterilization. Yet, incapable of allowing any detectable amount of

immobilized microorganism or enzyme to survive or remain active following a sterilization cycle which is lethal to the test microorganisms contained in the test pack commonly used to monitor sterilization.

The invention further provides a test pack for determining the efficacy of a sterilization cycle in a sterilization chamber comprising the biological

indicator of this invention within a test pack commonly used to monitor sterilization.

Additionally, the invention provides a method of increasing the thermostability of a

(1) viable microorganism commonly used to monitor sterilization, or

(2 ) another source of an active test enzyme known to be useful to monitor

sterilization , within a biological indicator comprising immobilizing the test microorganism and/or active enzyme.

The prior art discloses a number of methods of immobilizing various microorganisms and enzymes (e.g., U.S. Patent No. 4,663,287; Srivastava, Indian Journal of Biochemistry and Biophysics, Vol. 28, pp. 109-113 (April 1991); Biotechnology and Applied Biochemistry. Vol. 13, pp. 36-47 (1991); American Society for

Microbiology News, Vol. 55, pp. 67-70 (1989); Journal of Hygiene, Vol. 54(4), pp. 487-508 (1956); Food

Industries, March 1941, pp. 64-65; Food Research, Vol. 14., pp. 499-510 (1949); Journal of Bacteriology, Vol. 62, pp. 81-96 (1951); Journal of Bacteriology, Vol. 68, pp. 338-345 (1954); Journal of Applied Bacteriology, Vol. 37, pp. 31-43 (1974). However, none of these references disclose the use of immobilization to stabilize or protect biomaterial in dried form in a biological indicator from the lethal or inactivating effects of either steam or ethylene oxide

sterilization. The devices of the present invention are useful to determine the efficacy of a sterilization cycle in either gravity or prevacuum steam sterilizers or ethylene oxide sterilizers and are sufficiently accurate to pass AAMI standards. In preferred

embodiments, the devices of the present invention are disposable, pre-assembled, small, easy to use and convenient to handle.

Brief Description of the Figures

FIG. 1 is a cross-sectional view of one embodiment of a biological indicator of the present invention, with the closure device 26 removed.

FIG. 2 is an exploded perspective view of the biological indicator of FIG. 1, closure device 26 included.

FIG. 3 is a cross-sectional view of a preferred embodiment of an indicator of the present invention, with closure 56 in the closed position.

FIG. 4 is an exploded perspective view of the indicator of FIG. 3.

FIG. 5 is an exploded view of a test pack,

including a biological indicator of the invention.

FIG. 6 is a perspective view of the test pack of FIG. 5.

Detailed Description

Microorganisms which may be employed in the biological indicators of the present invention are those conventionally used microorganisms which are generally many times more resistant to the

sterilization process being employed than most

organisms encountered in natural contamination.

Favorable results have been obtained with bacteria and fungi which exist in both "spore" and "vegetative" states. The bacterial spore is recognized as the most resistant form of microbial life. It is the life form of choice in all tests for determining the sterilizing efficacy of devices, chemicals and processes. Spores from Bacillus and Clostridia species are the most commonly used to monitor sterilization processes utilizing saturated steam, dry heat, gamma irradiation and ethylene oxide.

Particularly preferred microorganisms include

Bacillus stearothermophilus, Bacillus subtilis, and Bacillus pumilus. Bacillus stearothermophilus is particularly useful to monitor sterilization under steam sterilization conditions. Bacillus subtilis is particularly useful to monitor conditions of gas and dry heat sterilization. Bacillus pumilus is

particularly useful to monitor gamma irradiation sterilization.

In a preferred biological embodiment of the present invention, the biological indicator includes a source of active immobilized enzyme.

The enzymes useful in the preferred embodiment are enzymes including extracellular and intracellular enzymes, whose activity correlates with the viability of at least one microorganism commonly used to monitor sterilization efficacy. The use of such enzymes to monitor sterilization efficacy is described in commonly assigned U.S. Patent No. 5,073,488. After the

indicator is subjected to a sterilization cycle the immobilized enzyme contained therein is mixed with an aqueous reaction mixture of a substrate for that enzyme. The reaction mixture is then evaluated in, e.g., a fluorometer or a colorimeter, to determine the presence of any enzyme-modified product. The existence of detectable enzyme-modified product above background within an established period of time (dependent upon the identity of the enzyme and the substrate, the concentration of each, and the incubation conditions) indicates a sterilization failure. The lack of

detectable enzyme-modified product within the

established period of time indicates a sterilization cycle which would have been lethal to the test organism and is therefore adequate.

Enzymes which have been found to be useful include hydrolytic enzymes from spore-forming microorganisms, as well as enzymes derived from animals or plants, such as almonds. Such enzymes include beta-D-glucosidase, alpha-D-glucosidase , alkaline phosphatase , acid

phosphatase, butyrate esterase, caprylate esterase lipase, myristate lipase , leucine aminopeptidase, valine aminopeptidase, chymotrypsin, phosphohydrolase, alpha-D-galactosidase, beta-D-galactosidase, alpha-L-arabinofuranosidase, N-acetyl-β-glucosaminidase, beta-D-cellobiosidase, alanine aminopeptidase, proline aminopeptidase, tyrosine aminopeptidase, phenylalanine aminopeptidase, beta-D-glucuronidase, and fatty acid esterase derived from spore-forming microorganisms , such as Candida , Bacillus , Neurospora , and Clostridium species of microorganisms .

The source of active enzyme may be:

1) the purified , isolated enzyme derived from an appropriate microorganism;

2 ) a microorganism to which the enzyme is indigenous or added by genetic engineering; or

3 ) a microorganism to which the enzyme has been added during sporulation or growth, such that the enzyme is incorporated or associated with the

microorganism, e.g. , an enzyme added to a spore during sporulation which becomes incorporated within the spore .

Advantageously, a microorganism which is itself one conventionally used to monitor sterilization conditions , is utilized as the source of active enzyme . Any of the microorganism which remains viable,

following the completion of the sterilization cycle, is incubated with nutrient growth medium to confirm by conventional technique whether the sterilization conditions had been sufficient to kill all of the microorganisms in the indicator, indicating that the sterilization conditions had been sufficient to

sterilize all of the items in the sterilizer .

A number of different means of immobilizing the microorganism or enzyme (referred to herein as the "biomaterial") may be utilized. One particularly useful technique is to chemically immobilize' the microorganism or enzyme using compounds (referred to herein as "immobilizing agents") which 1) form ionic and/or covalent bonds to the microorganism or enzyme thereby forming a stable immobilized complex; 2) coat or entrap the molecules of the biomaterial (referred to herein as the "biomolecules") with a hygroscopic or hydrophilic layer which protects against denaturation; or 3) dehydrate the outer membrane of the biomolecule to increase its thermostability.

Particularly useful immobilizing agents for use in steam sterilization include alditols, di and

trisaccharides and polymeric alcohols selected from polyvinyl alcohol, glycols and diols. For ethylene oxide sterilization, suitable immobilizing compounds include alditols; monosaccharides, including aldoses and ketoses; polysaccharides, such as di, tri, tetra, penta and hexasaccharides, starches, cyclodextrins, pectins, guar gum, gum tragantha, gum arabic,

celluloses and kappa carrageenan; polylactams, such as polyvinyllactams; and the polymeric alcohols described above.

The alditols and monosaccharides preferably consist of 3 to 6 carbon atoms. The di and

trisaccharides preferably have at least 4 carbon atoms per saccharide unit and the other polysaccharides preferably have 5 or 6 carbon atoms per saccharide unit. Preferably the alditols and saccharides have molecular weights of between about 100 and 100,000 daltons. The saccharides may be reducing or

nonreducing saccharides. Preserved polymeric alcohols have molecular weights of between about 200 and 100,000 daltons. Preferred polylactams have molecular weights of about 50 to 100,000 daltons. Particularly preferred alditols include glycerol, threitol, ribitol (commonly known as adonitol), arabinitol, xylitol, allitol, glucitol (commonly known as sorbitol), mannitol, iditol, galactitol (commonly known as dulcitol), altritol, erythitol, inositol, heptitol, octitol, nonitol, decitol, dodecitol, stracitol, and polyalitol.

Particularly preferred aldoses include

glyceraldehyde, threose, erythrose, ribose, arabinose, xylose, lyxose, allose, altrose, glucose, mannose, gulose, idose, galactose, talose, heptose, octose, nonitose, decitose, dodecitose, rhamnose, fucose, 2-deoxyribose, glucosamine, galactosamine,

3-dimethylamino-3, 6-dideoxyaltose, and 3-amino-3-deoxyribose.

Particularly preferred ketoses include

dihydroxyacetone, erythrulose, ribalose, xylolose, psicose, fructose, sorbose and tagatose.

Particularly preferred disaccharides include arabinopyranobiose, arabinofuranobiose, cellobiose, cellubiouronic acid, chitobiose, chondrosine,

galactobiose, galacturonic acid, gentobiose,

glucosylgalactose, glucosylglucosamine, hyalobiouronic acid, inulobiose, isomaltose, kojibiose, lactose, laminarabiose, maltose, mannobiose, melibiose,

4-methylglucosylxylose, nigerose, planteobiose, primaverose, rutinose, sophorose, sucrose, trehalose, turanose, vicianose, and xylobiose.

Particularly preferred trisaccharides include cellotriose, gentaianose, 6-O-glucosylmaltose,

isokestose, isomaltotriose, isopanose, kestose, laminaratriose, maltotriose, melezitose, neokestose, neuraminolactose, panose, planteose, raffinose, and umbelliferose.

Particularly preferred tetrasaccharides include cellotetraose, maltotetraose, and stachyose. A particularly preferred pentasaccaride is verbascose. Other preferred polysaccharides include cyclic

oligosaccharides, such as cyclomatohexaose,

cyclomaltoheptaose and cyclomalto-octaose; celluloses, such as methylcelluose, hydroxypropyl methyl cellulose, carboxymethylcellulose, and hydroxypropyl cellulose; gums; mucilages; pectins; hemicelluloses;

lipopolysaccarides; glycogen; chitin; and starch.

Particularly preferred polymeric alcohols include polyvinyl alcohol, propylene glycol, dipropylene glycol, polyethylene glycol (m.w. 200 - 100,000

daltons), polypropylene glycol (m.w. 200 - 10,000 daltons), ether alcohols, such as polyethylene glycol ether (m.w. 500 - 50,000 daltons), polypropylene glycol ether (m.w. 500 - 10,000 daltons), and diols, such as 1,3-butanediol, 1,5-pentanediol, 1,6-hexanediol,

1,7-heptanediol, 1,8-octanediol, 1,9-nonanediol and 1,10-decanediol.

Particularly preferred polyvinyl lactams include N-vinyl-2-pyrrolidone, 5-methyl-N-vinyl-2-pyrrolidone, 5-ethyl-N-vinyl-2-pyrrolidone, 3,3-dimethyl-N-vinyl-2-pyrrolidone, 3-methyl-N-vinyl-2-pyrrolidone, 3-ethyl-N-vinyl-2-pyrrolidone, 4-methyl-N-vinyl-2-pyrrolidone, 4-ethyl-N-vinyl-2-pyrrolidone, N-vinyl-2-valerolactam, and N-vinyl-2-caprolactam.

The immobilizing compounds or agents are

preferably utilized as coatings over microorganisms or enzymes contained on conventional carriers.

Alternatively, suspensions of the test microorganisms or enzymes in the immobilizing agents are prepared and these suspensions are coated upon conventional carrier strips and allowed to dry. The amount of immobilizing agent applied to the biomaterial is preferably about 1×10^-6 to 1×10^-12 g/spore or unit of enzyme, more

preferably about 1×10^-9 to 1×10^-11 g/spore or unit of enzyme, and most preferably 9×10^-10 to 1×10^-10 g/spore or unit of enzyme. Preferably aqueous solutions of the immobilizing agent in concentrations of 0.1 to 98 percent w/v, more preferably 1 to 70 percent w/v and most preferably 5 to 50 percent w/v are applied to the biomaterial. Preferably also the immobilizing agent is applied to the biomaterial so that the substrate upon which the dried biomaterial is carried includes

immobilizing agent at coating weight, of preferably about 1×10^-1 to 1×10^-7 g/mm², more preferably about 1×10^-4 to 1×10^-6 g/mm², and most preferably 9×10^-5 to 1×10^-5 g/mm².

The following tables list particularly preferred concentrations of a number of immobilizing agents in aqueous solution to be utilized to prepare stand alone biological indicators (BI) (i.e., without the use of towels, syringes or other test pack materials or

devices) and biological indicators to be used in

conventional test packs, for use in steam and ethylene oxide sterilization cycles.

For monitoring steam sterilization using 121°C gravity or 132°C prevacuum cycles:

Concentration Concentration for Stand for Test Pack

Immobilizing Agent Alone BI (w/v) (w/v)

lactose 50-98% 0.1-49% cellobiose 20-70% 0.1-19% maltose 40-98% 0.1-39% Trisaccharides

raffinose 40-98% 0.1-39% melezitose 30-70% 0.1-29% Polymeric Alcohols

polyethylene glycol 15-70% 0.1-14% polyvinyl alcohol 0.75-5% 0.1-0.74%

In more stringent steam sterilization cycles (e.g.

121°C or 134°C prevacuum) the concentration of

immobilizing agent for biological indicators in test packs may need to be increased by four to five times that indicated above.

For monitoring ethylene oxide sterilization:

Concentration Concentration for Stand Alone for Test Pack

Immobilizing Agent Alone BI (w/v) (w/v)

Monosaccharides

glucose 20-98% 0.1-19% ribose 30-90% 0.1-29% arabinose 5-70% 0.1-4% erythitol 5-70% 0.1-4% glycerin 10-98% 0.1-9% sorbitol 10-98% 0.1-9% adonitol 20-70% 0.1-19% xylitol 5-70% 0.1-4% Concentration Concentration for Stand Alone for Test Pack

Immobilizing Agent BI (w/v) (w/v) d-mannitol 10-70% 0.1-9% myo-inositol 10-70% 0.1-9% dulcitol 5-70% 0.1-4% arabinitol 10-70% 0.1-9% sorbose 5-98% 0.1-4% fructose 10-98% 0.1-9% Disaccharides

cellobiose 10-70% 0.1-9% lactose 10-98% 0.1-9% sucrose 10-98% 0.1-9% trehalose 20-98% 0.1-19% maltose 20-98% 0.1-29% Trisaccharides

raffinose 20-98% 0.1-19% melezitose 10-70% 0.1-9%

Polysaccharides

pectin 0.75-5% 0.1-0.7% gum guar 0.5-5% 0.1-0.4% gum arabic 0.75-5% 0.1-0.7% gum tragacantha 0.75-5% 0.1-0.7% kappa carragenan 0.75-5% 0.1-0.7% starch 10-70% 0.1-9% Concentration Concentration for Stand Alone for Test Pack

Immobilizing Agent BI (w/v) (w/v) Polymeric Alcohols

dipropylene glycol 20-98% 0.1-19% polyvinylpyrolidone 0.75-5% 0.1-0.7% polyvinyl alcohol 0.75-5% 0.1-0.7% polyethylene glycol 10-70% 0.1-9%

Adsorption of the microorganism or enzyme onto a water-insoluble support material is another method of immobilizing the biomolecule. Useful support materials bond to the microorganism or enzyme by weak bonding forces such as salt-linkages, hydrogen bonds and Van der Waals forces, and are capable of adsorbing at least 1×10² microorganisms or 0.1 unit of enzyme. Exemplary support materials include alumina, bentonite, calcium carbonate, calcium phosphate gel, cellulose (such as aminoethyl, carboxymethyl, diethylamino-ethyl,

palmitoyl, phenoxyacetyl, phosphate, tonnin-aminohexyl, tonnin-triethylaminoethyl, and tri-ethylaminoethyl celluloses), clay, collagen, dextrans (such as dextran sulfate), dextran derivatives (such as

"Sephadex® G-Types", commercially available from

Pharmacia), porous glass, hydroxyapatite, koalin, phenolic polymers, silica gel, agarose, "Sepharose® Ion Exchangers", commercially available from Pharmacia (such as concanavalin A-Sepharose) "Sephadex® Ion

Exchanger", commercially available from Pharmacia, carbon (such as activated, glossy, molecular sieve 4A, nylon or zeolite carbon), stainless steel, silochrome, titanium oxide, polystyrene and polypropylene. Enzymes or microorganisms can also be immobilized by water-insoluble support materials which form bonds to the biomolecule. Such support materials include groups which react with functional groups on the molecules of biomaterial (or biomolecules), such as the alpha- or epsilon-groups of lysine, tyrosine,

histidine, arginine or cysteine, so as to bond to at least 1×10² microorganisms or 0.1 unit of enzyme.

Useful support materials which form covalent bonds to biomolecules have covalent bonding groups such as hydroxyl, amino, carboxyl or sulfonic acid groups.

Particularly useful support materials for this type of immobilization include agarose, cellulose, dextran, glass, polyacrylamide co-polymers, polyamino styrene, collagen, polyhydroxyalkylmethacrylate, silica,

polyethylene, polyester, polystyrene, nylon, alkyl anhydride polymers, polythiol/4-vinylpyridine, gelatin, polyvinyl alcohol, polyethylene terephthalate,

polyacrylonitrile, chitin, polyurethane, carbon, silochrome, titania, ferrite, alumina, magnetic iron particles.

Useful support materials which form ionic bonds to biomolecules also have functional groups such as hydroxyl, amino, carboxyl or sulfonic acid groups.

Particularly useful support materials for this type of immobilization are described in references such as "Immobilized Enzymes and Cells", K. Mosbach, Academic Press, Inc. (1987), and include ionic celluloses, such as aminoethyl, carboxymethyl, diethylaminoethyl and triethylaminoethyl celluloses, ionic polystyrene (such as those available as "Amberlite" from Mallinckrodt Chemical Works, St. Louis, Missouri), dextran sulfate, and "Sephadex® Ion Exchangers", such as carboxymethyl, diethylaminoethyl, quaternaryaminoethyl and sulfopropyl "Sephadex® Ion Exchangers", commercially available from Pharmacia.

To immobilize using the support materials, the microorganism or enzyme is mixed with the support material in an aqueous medium at a pH which does not inhibit enzyme activity. Following a period of

incubation, the insoluble support material with

adsorbed or attached biomaterial is separated from the mixture by centrifugation or filtration. The solid recovered is then used as a carrier for immobilized biomaterial in biological indicator devices.

Another method of immobilizing enzymes or

microorganisms is to entrap the biomaterial in a chemically crosslinked polymer gel matrix. The gel is usually comprised of non-ionic polymer-forming

materials which are non-reactive with enzymes or microorganisms and are capable of entrapping at least 1×10² microorganisms or 0.1 unit of enzyme. Exemplary gels include polyacrylamide gels, polyacrylamide-hydrazide gels, calcium alginate gels, kappacarrageenan gels, agar gels, collagen, cellulose gels, chitosan gels, and methacrylate gels.

A still further means of immobilizing

microorganisms and enzymes is micro-encapsulation, whereby an artificial membrane is created around the biomolecule. Since the membrane forming process does not depend upon the particular biomolecule in solution, a number of membrane-forming materials may be used to encapsulate a variety of enzymes and microorganisms. Exemplary materials capable of microencapsulating biomolecules include cellulose acetate butyrate, cellulose nitrate, lipid-polyamide, polyethyleneimine nylon, nylon, bovine serum albumin,

polyvinylpyrolidone, poly(phthaloylpiperazine) and epoxy. Typical methods of encapsulation are described in Journal of Molecular Catalysis, Vol. 11, p. 83 (1981); Biotechnology and Bioengineering, Vol. 17, p. 1157 (1975); Enzyme and Microbiological Technology, Vol. 4, p. 327 (1982); Enzyme and Microbiological Technology, Vol. 6, p. 135 (1984); Enzyme and

Microbiological Technology, Vol. 3, p. 149 (1981);

Methods in Enzymology, Vol. 112, pp. 3-112 (1985); and U.S. Patent No. 4,147,767.

Crosslinking of enzymes or microorganisms through their side amino acid groups is another immobilization method. Immobilizing agents such as dialdehydes, diimido esters, diisocyanates, and bisdiazonium salts are used to form intra- or intermolecular crosslinking of the biomolecules. These agents must be capable of crosslinking at least 1×10² microorganisms or 0.1 unit of enzyme. Useful crosslinking methods are described in Annals New York Academy of Sciences, Vol. 542, pp. 173-179 (1988); Annals New York Academy of

Sciences, Vol. 434, pp. 27-30 (1984); Biotechnology and Applied Biochemistry, Vol. 9(5), pp. 389-400 (1987); Applied Biochemistry and Biotechnology, Vol. 15(3), pp. 265-278 (1987); Biotechnology Letters, Vol. 10(5), pp. 325-330 (1988); Archives of Biochemistry and

Biophysics, Vol. 275(1), pp. 23-32 (Nov. 15, 1989); and ACTA Biochimica Polonica, Vol. 34(2), pp. 145-156 (1987). Crosslinking stabilizes the conformational rigidity of the enzyme or biomolecule, thus preventing the biomolecule from being denatured by such things as heat and moisture. In summary, any of the immobilization methods described above, i.e., chemical immobilization, adsorption or bonding onto supports, entrapment, encapsulation or crosslinking, or any combination of these methods can be utilized in the practice of this invention. Regardless of the method of immobilization employed, the extent of immobilization required in order for the biological indicator of the present invention to provide results equivalent to AAMI test packs depends upon a number of factors. Such factors include the sterilization cycle parameters (e.g., temperature and sterilant concentration), whether conventional microorganism growth or use of enzyme substrates is used to evaluate sterility, and whether the biological indicator of the invention is used with or without a test pack.

To monitor sterilization with a stand alone biological indicator of the invention (i.e., without the use of towels, syringes or other test pack

materials or devices), the microorganism or enzyme is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a 15 minute exposure to a steam sterilization cycle of 121°C gravity, yet not capable of allowing any detectable amount of immobilized biomaterial to survive or remain active following an exposure of up to 45 minutes, more preferably up to 30 minutes, to this sterilization cycle. For use as a stand alone biological indicator in a steam sterilization cycle of 132°C prevacuum, the microorganism or enzyme is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a fifteen second, more preferably at least a one minute exposure to the cycle, yet not capable of allowing any detectable amount of

microorganism or enzyme to survive or remain active following an exposure of up to 15 minutes, more

preferably up to 10 minutes to the cycle. For use as a stand alone biological indicator in a steam

sterilization cycle of 121°C prevacuum, the

microorganism or enzyme is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a five minute exposure to the cycle, yet not capable of allowing any detectable amount of microorganism or enzyme to survive or remain active following an exposure to the cycle of up to 15 minutes. In a steam sterilization cycle of 134°C prevacuum, the microorganism or enzyme in the stand alone device is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a two second, more preferably at least a fifteen second exposure to the cycle, yet not capable of allowing any detectable amount of microorganism or enzyme to survive or remain active following an exposure to the cycle of up to 10 minutes, more preferably up to 6 minutes.

For use as a stand alone biological indicator in an ethylene oxide sterilization cycle, the

microorganism or enzyme is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a fifteen minute exposure, yet not capable of allowing any detectable amount of the biomaterial to survive or remain active following an exposure of up to 250 minutes to the ethylene oxide sterilization cycle. More preferably in an ethylene oxide sterilization cycle of 600 mg ethylene oxide per liter, 54°C and 60% relative humidity, the extent of immobilization is such that a detectable amount of biomaterial survives or remains active following at least a 20 minute exposure and no viable or active biomaterial is detected following a 60 minute, most preferably a 40 minute, exposure to the ethylene oxide cycle. In an ethylene oxide sterilization cycle of 800 mg ethylene oxide per liter, 37°C and 60% relative humidity, it is more preferred that the extent of immobilization is such that a detectable amount of biomaterial survives or remains active following at least a 20 minute exposure and no viable or active biomaterial is detected following a 120 minute

exposure, most preferably a 90 minute exposure, to the cycle.

When the biological indicator of this invention is used not as a stand alone device, but with conventional test pack materials (such as in a commercially

available test pack or in an AAMI test pack) the degree of immobilization may be reduced since the test pack materials protect the biomaterial by providing a challenge to the sterilant reaching the immobilized biomaterial.

To monitor sterilization with a biological

indicator of the invention placed within towels, syringes or other test pack materials or devices, the microorganism or enzyme is preferably immobilized to an extent that allows the biomaterial when tested in a stand alone device to exhibit the following

survival/kill characteristics. Preferably, the extent of immobilization is sufficient to allow a detectable amount of the immobilized biomaterial to survive or remain active following at least a 5 minute exposure to a steam sterilization cycle of 121°C, yet not capable of allowing any detectable amount of immobilized biomaterial to survive or remain active following an exposure of up to 15 minutes. For use with test pack materials in a steam sterilization cycle of 132°C prevacuum, the microorganism or enzyme in a stand alone device is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a 20 second exposure to the cycle, yet not capable of allowing any detectable amount of

microorganism or enzyme to survive or remain active following an exposure of up to 6 minutes to the cycle. For use with test pack materials in a steam

sterilization cycle of 121°C or 134°C prevacuum, the microorganism or enzyme in a stand alone device is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a 5 second exposure to the cycle, yet not capable of allowing any detectable amount of microorganism or enzyme to survive or remain active following an exposure to the cycle of up to 2 minutes.

For use with test pack material in an ethylene oxide sterilization cycle, the microorganism or enzyme in a stand alone device is preferably immobilized to an extent capable of allowing a detectable amount of the immobilized biomaterial to survive or remain active following at least a 15 minute exposure, yet not capable of allowing any detectable amount of the biomaterial to survive or remain active following an exposure of up to 90 minutes to the ethylene oxide sterilization cycle. More preferably in an ethylene oxide sterilization cycle of 600 mg ethylene oxide per liter, 54°C and 60% relative humidity, the extent of immobilization is such that a detectable amount of biomaterial survives or remains active following at least a 15 minute exposure and no viable or active biomaterial is detected following a 50 minute exposure to the ethylene oxide cycle. In an ethylene oxide sterilization cycle of 800 mg ethylene oxide per liter, 37°C and 60% relative humidity, it is more preferred that the extent of immobilization is such that a detectable amount of biomaterial survives or remains active following at least a 15 minute exposure and no viable or active biomaterial is detected following a 90 minute exposure to the cycle.

Preferably the method of detecting microorganism viability in the above-described tests is outgrowth in standard nutrient medium after 24 and 48 hours of incubation. The method of detecting enzyme activity is the use of enzyme substrate as described in U.S. Patent No. 5,073,488.

The construction of the biological indicator in which the immobilized microorganism or enzyme is contained is not crucial to this invention. Preferably the biological indicator is a unitary biological indicator, i.e., an indicator containing both the immobilized biomaterial and an enzyme substrate and/or nutrient growth medium. Exemplary structures for such indicators are disclosed in U.S. Patent Nos. 2,854,384; 3,346,464; 3,239,429; 3,440,144; 3,585,112; 3,661,717; 3,752,743; 3,846,242; 4,291,122; 4,304,869; 4,311,793; 4,416,984; 4,743,537; 4,596,773; 4,461,837; 4,528,268; 4,579,823; 4,580,682; 4,596,773; 4,717,661; and

4,885,253. A particularly preferred indicator

construction is described in commonly assigned U.S.S.N. 07/277,570. Any of these biological indicators would be useful in the practice of the present invention if the enzyme or microorganism is immobilized as described herein.

The following description is directed to

applicant's preferred embodiments. Many variations of the following devices are possible which will

nonetheless fall within the scope of the present invention.

Referring now to FIGS. 1 and 2, a preferred biological indicator is shown having an outer container 10 in the shape of cylindrical tube, having liquid impermeable walls 12, which are preferably gas non-adsorptive, and an open end 14. Outer container 10 contains a carrier 16, such as a strip of filter paper, bearing a predetermined amount of active enzyme and/or a predetermined number of viable microorganisms. Outer container 10 also includes a normally sealed, pressure-openable inner container 18, such as a frangible glass ampoule, containing an aqueous nutrient growth medium and/or a suitable enzyme substrate dissolved or

suspended in an aqueous buffered solution 20. The aqueous nutrient medium is capable, with incubation, of promoting growth of viable microorganisms when

contacted therewith, and preferably contains a

microbial growth indicator which provides a change in the color of the solution if viable microorganisms are present, indicating an inadequate cycle. The enzyme substrate is capable of reacting with active enzyme to yield a luminescent, fluorescent, colored or

radioactive material. The inner container 18 is preferably snugly retained within the outer container 10 so that very little of the volume of the outer container remains unoccupied. Inner container 18 is separated from the wall 12 of the outer container 10 by the filter paper carrier 16. The open end 14 of the outer container 10 is provided with a gas-transmissive, semi-porous closure member 22, such as a sheet. The closure member 22 may be sealed to the open end 14 of the outer container 10 by, e.g., heat or adhesive sealing, or by means of a closure device 26, such as a cap, (shown removed in FIG. 1) which has three

apertures 28 therethrough. During sterilization with a gaseous sterilization agent, the gaseous sterilant permeates the closure member 22 and passes through the interior of the outer container 10 to contact the immobilized biomaterial upon carrier 16.

As shown in FIG. 2, the apparatus of FIG. 1 may be easily assembled by sequentially inserting into the open end 14 of the outer container 10 the carrier 16 and the inner container 18 , and sealing the open end 14 of the outer container 10 with closure member 22 by placing closure member 22 over open end 14 and then placing closure device 26 over closure member 22, in closing engagement with outer container 10.

Outer container 10 is made from material which will withstand the high temperatures encountered in steam sterilizers. Conventional steam sterilizers generally reach temperatures on the order of

121ºC-135ºC. Additionally, the walls of container 10 must be substantially impermeable to liquids. Outer container 10 is preferably translucent (including "transparent") so that a change in fluorescence or color may be visually observed without disassembling the indicator device. Preferably, also, the outer container 10 is sufficiently deformable so that the pressure-openable inner container 18 is ruptured when the outer container 10 is deformed, by using external pressure. Outer container 10 can be made by injection molding or extruding suitable materials, including polycarbonate, polypropylene, polyamides,

polymethylpentenes and various polyesters.

The closure device 26 can be made from any

material that will withstand the sterilization

temperatures. As in the case of the outer container 10, suitable materials include polycarbonate,

polypropylene, polyamides, polymethylpentenes and various polyesters, with polypropylene being preferred.

The immobilized enzymes and/or the microorganisms which are employed in the present invention normally are carried on a suitable carrier 16. It is

contemplated, however, that the immobilized biomaterial may be carried by the inner walls of the outer

container 10, or the outer walls of the inner container 18, or that when the immobilized biomaterial is

contained in a solid support it is merely included within the outer container 10 and there is no need for a carrier 16. The carrier 16 preferably is water-absorbent, such as filter paper, and should not inhibit microorganism growth or enzyme activity. Sheet-like materials such as cloth, nonwoven polypropylene, rayon or nylon, and microporous polymeric materials are especially preferred. However, metal foil substrates, for example, aluminum or stainless steel may be used, as well as substrates of glass (e.g., glass beads or glass fibers), porcelain, or plastic. Additionally, the enzyme carrier can be constructed of a combination of materials such as paper secured to a plastic or glass backing strip.

To assure reproducibility, it is desired that outer container 10 contain a predetermined amount of immobilized biomaterial. Isolated enzyme is obtained by using general methods of protein purification, such as salt fractionation, chromatography and

electrophoresis as described in Colowick, S., and

Kaplan, N.O. (Eds), Methods in Enzymology, Academic Press, New York, Vols. I-VII, (1957-1964). Preferably the initial concentration of isolated enzyme to be immobilized is between about 0.001 to 10,000 units, more preferably between about 0.01 and 1,000 units of enzyme, and most preferably between about 0.1 and 100 units. Where an immobilized microorganism is utilized, it is likewise desirable to start with a predetermined approximate number of microorganisms. Where the microorganism is Bacillus stearothermophilus or

Bacillus subtilis the preferred number is about 1×10² to 1×10⁸ microorganisms. Where the microorganism is

B. stearothermophilus, about 1×10² to 1×10⁷

microorganisms is particularly preferred. Where

B. subtilis is employed, about 1×10⁶ to 1×10⁸

microorganisms is preferred. The enzyme or

microorganism is then immobilized in accordance with the methods described herein. Then preferably a suspension having a known volumetric concentration of immobilized microorganism or enzyme is prepared and a predetermined volume of this suspension is used to moisten carrier 16 (e.g., filter paper). Preferably at least 1×10² immobilized microorganisms or 0.1 unit of immobilized enzyme is placed upon carrier 16. The dried carrier is then used in outer container 10.

Inner container 18 contains an aqueous solution 20 of nutrient growth media and/or an appropriate enzyme substrate. The types of nutrient media usefully employed in the present invention are widely known to the art. Commonly known microbial growth indicators, which change color in the presence of viable

microorganisms, are preferably present in at least one of the containers. The growth indicator material preferably is soluble in, and imparts color (upon microorganism growth) to, the aqueous nutrient medium so that a change in color may be easily observed through the translucent walls of the outer container. In addition, when an enzyme substrate is also present, the growth indicator material is preferably selected so that it will not interfere with the color or

luminescence of any enzyme-modified product.

Enzyme substrate when present is preferably contained in inner container 18 in a buffered aqueous solution. The aqueous buffer acts as a reaction medium for the residual active enzyme and the enzyme substrate system after the inner container is ruptured. The ionic conditions of the buffered solution should be such that the enzyme and enzyme substrate are not effected. Preferably, an isotonic buffer, such as phosphate buffered saline solution, tris(hydroxymethyl) aminomethane-HCl solution, or acetate buffer is chosen.

While the enzyme substrate is normally included in pressure-openable inner container 18, it is

contemplated that the enzyme substrate in dry form could be included in outer container 10 along with enzyme carrier 16. In fact, the active enzyme and its substrate could be present in dry form in the same carrier 16. In this construction, inner container 18 would preferably carry the aqueous reaction medium necessary for the active enzyme and its substrate to react.

The inner container 18 which contains the aqueous solution 20 of enzyme substrate and/or which contains the aqueous nutrient medium, is of material which is impermeable to gases and liquids and is capable of being opened upon the application of pressure thereto (i.e., "pressure openable") to permit the enzyme substrate and/or nutrient medium to enter the outer container 10. The inner container 18 is preferably of frangible material, such as glass to permit breakage or crushing of the inner container 18 when the outer container 10 is deformed. In another embodiment, the inner container 18 may be sealed with a plug such that the plug is expelled to release the contents of the inner container 18 upon application of pressure. In still another embodiment, the closure device 26 may include an ampoule crushing device, as shown in U.S. Patent No. 4,304,869, wherein the closure has tabs depending from the bottom of the closure device which upon depression of the closure device serve to crush the ampoule. Similarly, the device of the present invention may be used in a system having an ampoule crushing pin disposed in the bottom of the outer container 10.

Outer container 10 has at least one opening therein to permit ingress of sterilant (e.g., steam, ethylene oxide). This opening is normally closed or plugged with a gas-transmissive, semi-porous means. Suitable means include closure member 22, made of fibrous materials such as cotton, glass wool, cloth, nonwoven webs made from polypropylene, rayon,

polypropylene/rayon, nylon, glass or other fibers, filter papers, microporous hydrophobic and hydrophilic films, open celled polymeric foams, and semi-permeable plastic films such as those described in U.S. Patent No. 3,346,464.

A preferred embodiment of a sterilization

indicator of the present invention is illustrated in FIGS. 3 and 4. The device includes an outer container 40, having liquid impermeable and preferably gas non-adsorptive walls 42 and an open end 44. The outer container 40 includes a pressure-openable inner

container 48 which contains an aqueous solution 50 of a suitable enzyme substrate and/or an aqueous nutrient medium. The open end 44 of the outer container 40 is covered by a gas-transmissive, semi-porous closure member 52. With that, the similarity between the device depicted in FIG. 1 ends. In the device of FIGS. 3 and 4, the carrier 46 is located at the bottom closed end of the outer container 40, and a barrier 47 is positioned like a plug between the carrier 46 and the pressure-openable inner container 48. The barrier 47 is preferably made from nonwoven webs of fibers such as cotton, rayon, polypropylene, polypropylene/rayon blends, nylon or glass. Most preferably barrier 47 is constructed from a polypropylene nonwoven web, such as "Thinsulate® 200-B brand Thermal Insulation,"

commercially available from 3M, St. Paul, MN.

Barrier 47 serves to isolate the carrier 46 from the inner container 48, thus eliminating cold spots where the inner container 48 may be positioned over the carrier 46. The existence of cold spots can cause condensation to collect on the carrier 46. The condensate may effect the activity of enzyme contained on the carrier 46. Barrier 47 is preferably made from a hydrophobic material so that growing microorganisms and/or enzyme-modified product concentrates around the carrier and does not diffuse rapidly into the area of the container which is on the other side of the

barrier. Maintaining a higher concentration of growing microorganisms and/or enzyme-modified product in the lower portion of the indicator enables the product, whether it be luminescent or colored to be detected after a shorter period of incubation than would be the case if the carrier 46 was reacted with the entire contents of inner container 48.

The closure 56 is comprised of a top 57 and depending sidewalls 59. The closure has a hollow body open at the bottom, with the interior diameter of the closure being about equal to the exterior diameter of outer container 40, so that closure 56 may be

frictionally engaged over the open end 44 of outer container 40. Cut within the sidewalls 59 are

preferably a plurality of windows 58. When the indicator device is placed in a load to be sterilized, the closure 56 is placed over the opening in the outer container in such a manner that the exterior sidewalls 42 of the outer container do not block windows 58. In such a position, sterilant in the sterilizer may enter outer container 40 by flowing through windows 58. Upon completion of the sterilization cycle, the closure may be fully inserted by depressing it to force the

sidewalls 42 of the outer container into engagement with the interior surface of top 57 thereby blocking windows 58. The interior of the outer container 40 is then sealed from the outside environment.

In use, the biological indicator depicted in FIGS. 3 and 4 is placed in a sterilizer chamber together with a number of items to be sterilized by, for example, steam or ethylene oxide gas. When the indicator is in the sterilizer, the closure 56 is in the open position, such that windows 58 are open permitting entry of the sterilant. When the sterilizing agent is introduced into the chamber, the sterilant permeates through the closure member 52 and passes barrier 47 to inactivate the enzyme and kill the test microorganisms present on carrier 46. At the end of the sterilization cycle, the sterilant is replaced with filtered air. The sterility indicator is withdrawn from the sterilizer, the closure 56 is fully inserted to block windows 58, and glass ampoule 48 is broken by, for example, finger pressure, causing the aqueous solution of enzyme substrate and/or nutrient growth media to contact the enzyme carrier 46. The indicator is then placed in a suitable incubating environment.

After the appropriate incubation period, the occurrence of a change in color or luminescence is observed or measured spectrophotometrically through the translucent walls 42 of the outer container 40, and indicates that the sterilization cycle had not

inactivated all the active enzyme or killed all the microorganisms present on the carrier 46 hence

indicating that the sterilization cycle was perhaps insufficient to completely sterilize the items in the sterilizer. The absence of any change in color or luminescence indicates that the sterilization cycle had been sufficient to inactivate all of the enzyme or kill all of the test microorganisms on the carrier 46, and hence was sufficient to sterilize the items in the sterilizer.

The biological indicator of this invention may be utilized in any type of conventionally used test pack materials or devices. Exemplary test packs include the "1278 Attest™ EO Pack" and "1276 Attest™ Steam Pack", both commercially available from 3M, and those devices disclosed in U.S. Patent Nos. 4,739,881; 4,828,797; 4,839,291; 4,636,472; 4,918,003; and in European Patent Nos. 421,760; 419,282; and 255,229. The biological indicator of this invention may also be used in plastic syringes, towel packs or other test pack devices as recommended by AAMI, the British Department of Health Standards, the German Industrial Norm standards and the Committee of European Normalization. Applicant has found that the use of immobilized biomaterial provides test packs which can more readily replicate these standards in more rigorous sterilization conditions, such as a 121°C gravity and prevacuum and 132°C and 134°C prevacuum steam sterilization cycles. This is particularly true where enzyme activity is used to evaluate sterilization efficacy, as described in U.S. Patent No. 5,073,488.

FIGS. 5 and 6 show a preferred test pack 100 containing the biological indicator 11 of this

invention. The test pack 100 is similar to that disclosed in U.S. Patent No. 4,918,003 and is comprised of a box 102 which may, for example, have overall dimensions of 134 mm by 140 mm by 28 mm. The box is made of bleached sulfate paper unvarnished.

The box contains an open container 108 also made of bleached sulfate paper which is coated on its exterior surfaces with a steam impermeable

thermoplastic coating 110 such as a polypropylene laminate. Container 108 is dimensioned to be only slightly smaller than the box 102.

Two stacks of sheets, 112 and 114, of semi-porous material separated by a stack of sheets 116 also of semi-porous material are contained within container 108. Each of the stacks of semi-porous material is preferably formed of filter paper having an approximate basis weight of 97 kg (214 pounds) per 280 m² (3,000 ft²) and an approximate thickness of 1 mm per sheet. Stacks 112 and 114 preferably include 20 to 55 sheets of filter paper.

The semi-porous stack 116 may be composed of approximately 16 sheets of filter paper with a 13 mm by 49 mm area 118 cut from the center of each sheet in order to receive biological indicator 11 of this invention. The height of this central core, when assembled and dry, is approximately 10 mm.

In practice applicant's test pack is opened by opening the box flap 122, the top semi-porous sheets are removed and the biological indicator 11 surrounded by a coiled metal spring 120, preferably made of stainless steel, is placed within the cavity in the center portion of the stack. The coiled spring 120 reduces the compression of the filter paper stacks upon the biological indicator 11 during the sterilization cycle so as not to prematurely crush inner container 18. The top sheets are then replaced and the box closed. The box is then placed in a sterilizer with a normal load and run through a conventional cycle.

Failure of the sterilant to penetrate the porous and semi-porous stacks due to the presence of air pockets in the sterilizer or due to insufficient time, temperature, etc., of the sterilization cycle, will prevent the sterilant from killing the microorganisms or inactivating enzyme within the biological indicator.

Once the sterilization cycle is completed, the test pack 100 is removed from the sterilizer, the box flap 122 is opened and the stacks of sheets are removed to provide quick access to the biological indicator 11. The biological indicator is then incubated with the nutrient growth solution and/or enzyme substrate to reveal any change in color or fluorescence.

The test pack of the present invention replicates the steam permeability qualities of the standard biological test pack described in the AAMI standard and reveals a lack of sterility under substantially the same conditions as the standard AAMI test pack.

The biological indicator and test pack of the present invention have been described primarily with reference to sterilizing media such as ethylene oxide, a variety of steam sterilization cycles (including 121°C prevacuum and gravity, and 132°C and 134°C prevacuum) and the like. The indicator is not,

however, limited to these uses, and may as well be used to indicate the efficacy of other sterilizing media, such as dry heat, radiation, propylene oxide, methyl bromide, ozone, chlorine dioxide, formaldehyde, and other gaseous and liquid agents.

The invention will be illustrated by the following non-limiting examples. Examples

Example 1

This example illustrates that the biological indicators of this invention comprising immobilized spores and enzyme and without the use of a conventional test pack device can provide sterilization efficacy results comparable with conventional biological

indicators (BIs) in an AAMI sixteen towel test pack at conditions of both 121°C (250°F) gravity and 132°C (270°F) prevacuum sterilization exposures.

Preparation of Spore Strips

Bacillus stearothermophilus commercially available as "ATCC 7953" from American Type Culture Collection, Rockville, MD., was grown overnight for approximately 16 hours at 58°C in tryptic soy broth. This culture was used to inoculate the surfaces of agar contained in plates consisting of 8 g/l nutrient broth, 4 g/l yeast extract, 0.1 g/l manganese chloride, and 20 g/l agar at pH of 7.2. Inoculated plates were incubated at 58°C for 72 hours. Spores were taken from the plates and

suspended in sterile distilled water. The spores were separated from vegetative debris by centrifuging the suspension at 7000 rpm at 4°C for 20 minutes. The supernatant was poured off and the spores were

resuspended in sterile distilled water. This cleaning procedure was repeated several times.

The Bacillus stearothermophilus spores were coated and dried on 6.35×9.52 mm (1/4×3/8 inch) strips of filter paper, commercially available as "S&S #903 Grade Filter Paper" from Schleicher & Schuell, Inc., Keene, NH, at a population of 7.5×10⁵ spores per strip. This was accomplished by preparing a suspension of the spores in water at a concentration of 7.5×10⁷ spores/ml, and pipetting 10 μl of this suspension onto each filter paper strip and allowing the strip to dry under ambient conditions.

Immobilization of Spores

The following method of immobilizing the spores and spore bound enzyme contained on the spore strips was employed. The spore strips of Bacillus

stearothermophilus were coated with one of the

following aqueous chemical immobilizer solutions:

"D-Sorbitol," commercially available from Pfizer, New York, NY, or "polyethylene glycol commercially

available as "Carbowax® PEG-1450" from Union Carbide Corporation, Danbury, CT, at percent concentrations (w/v) specified in Tables 1 and 2 to obtain coating weights of approximately 2.75×10^-5 to 3.75×10^-5 g/square millimeter per individual strip. This was accomplished by pipetting 50 μl of one of the immobilizer onto the spore strip and allowing the coated spore strips to dry under ambient conditions for 24 hours.

Assembly of Devices of Invention

Devices were constructed as illustrated in FIGS. 3 and 4, with the immobilized spore strip 46 on the bottom of the outer compartment of the vial 42 and a barrier 47 between the enzyme substrate-containing ampoule 48 and the spore strip. A 1.75 cm (11/16 inch) diameter disc of polypropylene blown microfiber

material with a weight of 200 g/sq. meter, commercially available as "Thinsulate® 200-B brand Thermal

Insulation" from 3M, St. Paul, MN, was used as the barrier 47. The ampoule 48 contained 0.67 ml of nutrient medium consisting of 17 g of bacteriological peptone and 0.17 g of L-alanine, as well as 0.1 g of the enzyme substrate, 4-methylumbelliferyl-alpha-D-glucoside, commercially available from Sigma Chemical Co., St. Louis, MO, and 0.03 g of bromocresol purple pH indicator dye per liter of distilled water. The pH of the enzyme substrate and nutrient medium was adjusted to 7.6 with 1.0 N sodium hydroxide. The outer

container 42 and the closure 56 were made from

polypropylene. The outer container 42 was 5.08 cm (2.0 in) long, with an outer diameter of 89 mm

(0.335 in) and an internal diameter of 85 mm

(0.303 in). The closure 56 was 1.66 cm (0.510 in) long with an internal diameter of 1.07 mm (0.328 in). The inner ampoule 48 was made of glass and was 3.96 cm (1.56 in) long, with an outer diameter of 6.5 mm

(0.258 in) and a wall thickness of 2.5 mm (0.010 in). The closure member 52 was a 1.27 cm (0.5 in) diameter piece of "Monatec 5111-067," suture stock, commercially available from Monadnock Paper Mills, Inc., Bennington, NH.

Assembly of Conventional Test Packs

The performance of six to eight unit batches of the above-described biological indicator devices was compared with conventional Association for the

Advancement of Medical Instrumentation (AAMI) steam test packs and with conventional biological indicators not contained in test packs. Each AAMI towel pack consisted of 16 freshly laundered "huck towels"

commercially available from American Linen Supply Co., Minneapolis, MN, in good condition, each of which was approximately 40.6×66 cm (16×26 inches). Each towel was folded lengthwise into thirds and folded widthwise in half. The towels were then placed on top' of one another with folds opposite each other to form a stack approximately 23×23×15 cm (9×9×6 inches). Into each towel stack, four "Attest™ 1262/1262P Biological

Indicators" (Lot #057, Dec. 91) or four "Attest™ 1291 Rapid Readout Biological Indicators" (Lot #085, Dec. 91) commercially available from 3M, St. Paul, MN, were placed between the 8th and 9th towels from the bottom of the stack. The test packs were secured with

autoclave tape.

Comparative Test

The devices of the invention and controls

(consisting of a conventional Attest™ 1262/1262P

Biological Indicator and a control biological indicator made as described above but without immobilization) not contained within AAMI test packs and placed within metal instrument trays, and the conventional AAMI biological test packs were exposed for 16, 18, 20, 22, and 24 minute intervals at a 121°C (250°F) gravity cycle (Table 1), and for 0, 1.5, 3.0 and 10.0 minute intervals at a 132°C (270°F) prevacuum cycle, 2 pulse, (Table 2), in a gravity displacement and vacuum

assisted steam sterilizer, commercially available as an "Amsco Eagle™ Model 3000," from American Sterilizer Company, Erie, PA. Following exposure, the

conventional biological indicators were removed from the AAMI sixteen towel test pack. The inner ampoules of both the indicators of this invention and the conventional biological indicators were crushed and the units were incubated at 60°C. For the devices

utilizing an enzyme substrate to indicate spore survival (i.e., all of the invention and the

conventional test packs including the 1291 "'Attest™ Biological Indicator (BI)"), an "Attest™ 190

Auto-Reader" commercially available from 3M, St. Paul, MN, was used to fluorometrically read alpha-glucosidase activity by measuring 4-methylumbelliferyl fluorescence after 4 and 8 hours of incubation. Spore growth, as indicated by a color change produced by the pH

indicator, was visually determined at 24, 48, and 168 hours of incubation for all units.

The results are reported in Tables 1 and 2. In the Tables of the Examples BI stands for "biological indicator".

The data presented above demonstrates that the biological indicators of the invention, utilizing spores and spore bound enzymes immobilized with

D-sorbitol and polyethylene glycol can provide

survival/kill and readout reliability results

comparable with conventional biological indicators used in AAMI test packs. The biological indicators of the invention provide quick and convenient detection of sterilization efficacy, without the need to employ test pack materials or devices.

Example 2

This example illustrates that biological

indicators of the invention utilizing immobilized alpha-glucosidase provide sterilization efficacy results comparable with conventional biological

indicators in an AAMI sixteen towel test pack, at 121°C (250°F) gravity and 132°C (270°F) prevacuum

sterilization exposures.

Preparation of Enzyme Strip

Lyophilized, purified alpha-glucosidase (Lot #001) derived from Bacillus stearothermophilus and with specific activity of 100 units/mg was obtained from Unitika Ltd., Kyoto, Japan. The alpha-glucosidase (0.1 g) was suspended in 1 ml of sterile distilled water. The enzyme suspension was dialyzed against 1 liter of sterile distilled water for 24 hours using a "Spectra/Por® Molecularporous Membrane" commercially available from Spectrum Medical Industries Inc.,

Los Angeles, CA, at a molecular weight limit of 3500 daltons. The dialyzed enzyme suspension was stored at 4°C until needed. Dilutions of dialyzed alpha-glucosidase were made in sterile distilled water to give final concentrations of enzyme of 750 and 1500 units/ml. These dilutions of alpha-glucosidase were coated and dried on 6.35×28.58 mm (1/4×3/8 inch) strips of filter paper, commercially available as "S&S #903 Grade Filter Paper" from Schleicher & Schuell, Inc., Keene, NH. This was accomplished by pipetting 100 μl of each suspension onto each filter strip and allowing the strip to dry under ambient conditions.

Immobilization of Enzyme

The following method of immobilization of enzyme was employed. Strips of alpha-glucosidase were coated with the following aqueous chemical immobilizer

solutions: "D-Sorbitol" commercially available from Pfizer, New York, NY, and polyethylene glycol

commercially available as "Carbowax® PEG-1450" from Union Carbide Corporation, Danbury, CT, at percent concentrations (w/v) specified in Tables 3 and 4 to obtain coating weights of approximately 2.75×10^-5 to 3.75×10^-5 g/square millimeter per individual strip.

This was accomplished by pipetting 50 μl of the above solution of immobilizer compounds onto the enzyme coated strip. Immobilized enzyme strips were allowed to dry under ambient conditions for 24 hours, and devices were assembled. Assembly of Devices

Devices were constructed utilizing the immobilized enzyme strip as illustrated in FIGS. 3 and 4, and described in Example 1.

Ten unit batches of the above-described biological indicator device (placed in metal instrument trays) and conventional biological indicators in Association for the Advancement of Medical Instrumentation (AAMI) steam test packs were exposed to a sterilization cycle as described in Example 1.

The devices of the invention and the conventional

AAMI biological test packs were simultaneously exposed for 16, 18, and 20 minute intervals at a 121°C (250°F) gravity cycle (Table 1) and for 0, 1.5, and 3.0 minute intervals at a 132°C (270°F) prevacuum, 2 pulse cycle, (Table 2) in the sterilizer described in Example 1. After exposure, the conventional biological indicators were removed from the AAMI test packs, the inner ampoules of both the devices of the invention and the conventional biological indicators were crushed and the units were incubated at 60°C. Enzyme activity and spore growth were measured as described in Example 1. Spore growth could not be measured with the devices of the invention, since they utilized purified enzyme rather than spores to detect sterilization failure.

The results are reported in Tables 3 and 4.

The data presented above demonstrates that the biological indicators of the invention utilising alpha-glucosidase immobilized with D-sorbitol and PEG-1450 can provide survival/kill readout comparable to

conventional biological indicators used in AAMI test packs.

Example 3

This example illustrates the correlation between the biological indicators of this invention and

conventional biological indicators in an AAMI sixteen towel test pack, to determine the efficacy of

sterilization cycles of 121°C (250°F) gravity and 132°C (270°F) prevacuum.

Bacillus stearothermophilus commercially available as "ATCC 7953" from American Type Culture Collection, Rockville, MD, was grown as described in Example 1.

The Bacillus stearothermophilus spores were coated on filter paper dried, and immobilized as described in Example 1, except at a population of 1×10⁵ spores per strip. This was accomplished by preparing a suspension of the spores in water at a concentration of 1×10⁷ spores/ml, and pipetting 10 μl of this suspension onto each filter .paper strip and allowing the strip to dry under ambient conditions.

Devices as illustrated in FIGS. 1 and 2 were constructed utilizing the immobilized spore strip as described in Example 1 except that the device contained no barrier 47.

Three unit batches of the devices containing immobilized Bacillus stearothermophilus spores and controls (Attest™ 1262/1262P and the control biological indicator made in accordance with Example 1) not contained within test packs and placed in metal

instrument trays, and conventional biological

indicators in AAMI steam test packs (prepared as described in Example 1) were exposed to steam

sterilization cycles of 121°C (250°F) gravity (Table 5) and 132°C (270°F) prevacuum (Table 6) and evaluated for spore growth as described in Example 1.

The results are reported in Tables 5 and 6.

The devices of this invention were designed to provide microbial challenge during exposure to 121°C (250°F) gravity and 132°C (270°F) prevacuum steam cycles which is equal to or greater than the microbial challenge provided by the AAMI biological indicator test packs. The data presented above demonstrates that the invention utilizing D-sorbitol and PEG-1450 immobilized spores achieves and out-performs these requirements.

Example 4

This example illustrates the effect of various concentrations of the immobilizing agents, D-sorbitol and PEG-1450, on survival/kill times for Bacillus stearothermophilus ATCC 7953 immobilized spores and spore bound enzyme at 121°C (250°F) gravity exposures.

All spores were grown on nutrient agar medium as described in Example 1.

The Bacillus stearothermophilus spores were coated, dried, and immobilized as described in

Example 1.

Devices were constructed as illustrated in FIGS. 3 and 4 and described in Example 1.

Three unit batches of the devices described above and the biological indicator control made in accordance with Example 1 were placed in metal instruments trays and exposed for 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, and 25 minutes in a 121°C (250ºF) gravity steam sterilization cycle as described in

Example 1. The inner ampoules of the devices were crushed, and the units incubated at 60°C. Enzyme activity and spore growth were evaluated as described in Example 1. Enzyme activity is reported in Table 7 and spore growth is reported in Table 8.

The data presented above demonstrates that

immobilization of spores and spore bound enzymes with increasing concentrations of D-sorbitol and PEG-1450 increases the exposure time required to kill the spores and destroy enzyme on the spore strip.

Example 5

This example illustrates the use of D-sorbitol to enhance the survival/kill performance of the spore bound enzyme and spore when used in conventional test packs (as shown in FIG. 5) at 132°C (270°F) prevacuum exposure.

All spores were grown on nutrient agar medium as described in Example 1.

Suspensions of Bacillus stearothermophilus spores and D-sorbitol in water at the percent weight

concentrations indicated in Table 11 were made. This was accomplished by suspending washed Bacillus

stearothermophilus spores at a concentration of 7.5×10⁷ spores/ml into 10% and 20% w/v suspensions of D-sorbitol. The suspensions were mixed, coated, and dried on 6.35×9.52 mm (1/4×3/8 inch) strips of filter paper, commercially available as "S&S #903 Grade Filter Paper" from Schleicher & Schuell, Inc., Keene, NH, at a population of 7.5×10⁵ spores per strip. This was accomplished by pipetting 10 μl of suspension onto each filter strip and allowing the strip to dry under ambient conditions.

Three unit batches of the devices described above and conventional biological indicators ("Attest™ Rapid Readout Biological Indicator 1291" (Lot #085, December 1991)) were placed into "Attest™ 1276 test packs," commercially available from 3M, St. Paul, MN.

The test packs utilizing the biological indicators of the invention and the conventional biological indicator packs were exposed for 0.5, 1, and 4 minute intervals to a 132°C (270°F) prevacuum steam

sterilization cycle, 2 pulse, as described in

Example 1. The biological indicators were removed from the test packs, the inner ampoules were crushed, and each unit was incubated at 60°C. Enzyme activity and spore growth were evaluated as described in

Example 1. The results are reported in Table 9.

The data presented above demonstrates that

Bacillus stearothermophilus spores and spore bound enzyme, alpha-glucosidase, immobilized with relatively low concentrations of D-sorbitol can increase the survival time for spores in conventional test packs to exceed the performance of conventional biological indicators in those test packs. Increased spore survival time improves the performance of the test pack because a greater portion of the sterilization cycle can be monitored.

Example 6

This example illustrates the use of other

immobilizing compounds to immobilize Bacillus

stearothermophilus spores. The following list of compounds (and sources) were utilized:

"myo-erythritol," Sigma® Chemical Co., St. Louis, MO

"adonitol," Sigma® Chemical Co.

"dulcitol," Sigma® Chemical Co.

"D-mannitol," Sigma® Chemical Co.

"xylitol," Sigma® Chemical Co.

"D-arabinitol," Sigma® Chemical Co.

"D(+)-cellobiose," Sigma® Chemical Co.

"sucrose," Sigma® Chemical Co.

"meso-inositol," Sigma® Chemical Co.

"glycerol," Aldrich Chem. Co., Inc., Milwaukee, WI

"polyvinylalcohol (PVA)," Aldrich Chem. Co., Inc.

"trehalose," Sigma® Chemical Co.

"lactose," Sigma® Chemical Co.

"raffinose," Sigma® Chemical Co.

"melezitose," Sigma® Chemical Co.

"maltose," Sigma® Chemical Co.

Bacillus stearothermophilus commercially available as "ATCC 7953" were grown as described in Example 1.

The Bacillus stearothermophilus spores were coated at a population of 1×10⁵ spores per strip, dried, and immobilized as described in Example 1 with one of the chemical immobilizers listed above.

Devices were constructed utilizing the immobilized spore strip as illustrated in FIGS. 1 and 2 and

described in Example 3. Three unit batches of the devices described above (placed in metal instrument trays) and conventional biological indicators in AAMI steam test packs (as described in Example 1) were simultaneously exposed for 15, 18, 21, 24, 27, and 30 minute intervals to a 121°C (250°F) gravity steam sterilization cycle as described in Example 1. The inner ampoules of the biological indicators were crushed, and the units incubated at 56°C. Spore growth was evaluated as described in

Example 1, and the results are reported in Table 10.

The data presented above demonstrates the use of a variety of immobilizing compounds to provide

biological indicators which have survival/kill time points and readout reliability comparable to

conventional biological indicators utilizing test packs.

Example 7

This example illustrates several enzymes,

associated with Bacillus stearothermophilus, which are useful in the practice of the present invention. In this example an enzyme substrate kit, commercially available as "API-XYM™ System" from API Analytab

Products, Plainview, NY, was utilized. This kit consisted of 19 different dehydrated, chromogenic enzymatic substrates, packed individually in a series of microcupules. The addition of an aqueous sample to each microcupule rehydrates the substrate. The test kit was incubated for a desired time interval and the reactions were visually read after the addition of the detector reagents supplied with the system.

Bacillus stearothermophilus spores "ATCC 7953" were grown as described in Example 1.

The Bacillus stearothermophilus spores were coated and dried on strips of filter paper as described in Example 1 at a population of 1×10⁵ spores per strip. This was accomplished by preparing a suspension of the spores in water at a concentration of 1×10⁷ spores/ml, and pipetting 10 μl of this suspension on each filter strip and allowing the strip to dry under ambient conditions. The spores were immobilized as described in Example 1 using "D-Sorbitol" at a percent

concentration of 30 percent, weight to volume.

Devices were constructed using the spore strips as illustrated in FIGS. 3 and 4 and described in

Example 1.

Three unit batches of the device of the invention were exposed for 15 and 30 minutes at a 121°C (250°F) gravity cycle in the sterilizer as described in

Example 1. Following exposure, the spore strips were aseptically removed and transferred to each microcupule in the enzyme substrate kit and 100 μl of sterile tryptic soy broth was added to each well. One kit contained the immobilized spore strips exposed for 15 minutes, a second kit contained the immobilized spore strips exposed for 30 minutes, and the third kit contained unexposed immobilized spore strips.

The kits were incubated at 56°C for 7.5 hours. After incubation, the detector reagents A and B, available with the API-XYM™ system were added for substrate development. The detection of color in each microcapsule indicates the presence of active enzymes. Results are reported in Table 11.

The data presented above demonstrates a number of enzymes indigenous to Bacillus stearothermophilus spores which have sufficient activity to be useful in the practice of the invention. All of the enzymes evaluated which were indigenous to Bacillus

stearothermophilus showed detectable activity after an ineffective sterilization cycle of 15 minutes, but no activity after exposure for 30 minutes. Several enzymes are not indigenous to Bacillus

stearothermophilus and displayed no activity in the exposed or unexposed state.

Example 8

This example illustrates the use of various chemicals to immobilize Bacillus subtilis spores. The following immobilizer compounds (listed with their sources) were utilized:

"myo-erythritol," Sigma® Chemical Co., St. Louis, MO "adonitol," Sigma

"dulcitol," Sigma

"D-mannitol," Sigma

"xylitol," Sigma

"polyol-P," Pfizer, New York, NY

"D-arabinitol," Sigma

"D(+) -cellobiose," Sigma

"sucrose," Sigma

"myo-inositol," Sigma

"glycerol," Aldrich Chemical Co., Inc., Milwaukee, WI "dipropylene glycol," Aldrich

"polyvinylalcohol," Aldrich

"polyvinylpyrrolidone K-90," GAF® Chem. Co., Wayne, NJ "trehalose," Sigma

"L-sorbose," Sigma

"lactose," Sigma

"D-glucose," Sigma

"raffinose," Sigma

"melezitose," Sigma

"D-fructose," Sigma

"L-arabinose," Sigma

"starch,"

"sorbitol," Pfizer "cyclodextrin," American Maize-Product Co., Hammond, Indiana

"D-ribose," Sigma

"pectin," Sigma

"gum guar," Sigma

"gum tragacantha," Sigma

"gum arabic," Sigma

"kappa carrageenan," Sigma

"maltose," Sigma

"polyethylene glycol (Carbowax® PEG-1450)," Union

Carbide

"ATCC 9372" Bacillus subtilis was grown for 16 hours at 37°C in tryptic soy broth. This culture was used to inoculate the surface of agar plates consisting of 8 g/l nutrient broth, 0.011 g/l manganese sulfate, and 20 g/l agar at pH 7.2. The plates were incubated at 37°C for 6 days and the spores were scraped from the plates and suspended in sterile distilled water. The spores were separated from vegetative debris by

centrifuging the suspension at 7000 rpm and 4°C for 20 minutes. The supernatant was poured off and the spores were resuspended in sterile distilled water. This cleaning procedure was repeated several times.

The Bacillus subtilis spores were coated and dried on 6.35x28.58 mm (1/4×3/8 inch) strips of filter paper as described in Example 1 at a population of 1×10⁶ spores per strip. The spore strips of Bacillus

subtilis were coated with a solution of one of the immobilizers listed above at percent concentrations (w/v) specified in Table 12, as described in Example 1, and allowed to dry.

Devices were assembled using the immobilized spore strips, as shown in FIGS. 1 and 2 and as described in Example 3.

Three unit batches of the devices described above and the control made in accordance with Example 1, both placed in metal instrument trays, and conventional biological indicators ("Attest™ Rapid Readout 1264 Biological Indicator") in "Attest™ 1278 test packs" (Lot #215, June 1992), commercially available from 3M, St. Paul, MN, were preconditioned at 54°C and 60% relative humidity for 30 minutes and then exposed for 15, 18, 21, 24, 27, and 30 minute intervals at 54°C and 60% relative humidity, to 600 mg/L of ethylene oxide in a "Joslyn EO Bier Vessel," ethylene oxide sterilizer, commercially available from Joslyn Valve, Macedon, NY.

After exposure, the inner ampoules of the devices of the invention were aseptically removed and 0.67 ml of a solution of 17 g/L bacteriological peptone, 0.17 g/L L-alanine, and 0.03 g/L triphenyltetrazolium chloride was added to the outer vial of each unit. The conventional biological indicators were removed from the test packs and their inner ampoules crushed. All units were incubated at 37°C. Spore growth, as

indicated by a color change produced by the pH

indicator, was visually determined at 24, 48, and 168 hours of incubation.

The results are reported in Table 12.

The data demonstrates that immobilized Bacillus subtilis spores used without conventional test packs provide ethylene oxide sterilization indicators with survival/kill time points as good as or better than conventional ethylene oxide biological indicators in conventional test packs. However, spore survival after 30 minute exposures indicates a need to decrease the immobilizer concentration in order for the indicator of the invention to simulate conventional biological indicator test packs.

Example 9

This example illustrates the use of the compounds listed in Table 13 (polyols and related compounds need broad description for immobilizing compounds useful with ethylene oxide) to immobilize Bacillus subtilis spores and their exoenzyme beta-glucosidase.

"ATCC 9372" Bacillus subtilis spores were grown as described in Example 8. The Bacillus subtilis spores were coated, dried, and immobilized as described in Example 8, except at a population of 1×10⁷ spores per strip.

Devices were assembled using the immobilized spore strips, as shown in FIGS. 3 and 4, and as described in Example 1.

Three unit batches of these devices were placed in metal instrument trays along with the unit batches of conventional biological indicators, "Attest™ Ethylene Oxide Biological Indicator 1264" in "1278 Attest™ Test Packs, "(Lot #215, June 1992) commercially available from 3M, St. Paul, MN. The invention and the

conventional biological indicators in test packs were preconditioned at 54°C and 60% relative humidity for 30 minutes. The devices were then exposed for 20, 30, 60, and 120 minutes at 54°C and 60% relative humidity, to 600 mg/l of ethylene oxide in a "Joslyn EO Bier

Vessel," commercially available from Joslyn Valve, Macedon, NY.

After exposure, the inner ampoules of the devices of the invention were removed aseptically, and 0.67 ml of a solution of 17 g/l bacteriological peptone, 0.17 g/l L-alanine, 0.03 g/l triphenyltetrazolium chloride, and 0.1 g/l of 4-methylumbelliferyl-beta-D-glucoside, commercially available from Sigma Chemical Co., St. Louis, MO, was added to each unit. The conventional biological indicators were removed from the test packs and their inner ampoules crushed. All units were incubated at 37°C. An "Attest™ 190 Auto-Reader", commercially available from 3M, was used to

fluorometrically read beta-glucosidase activity by measuring 4-methylumbelliferyl fluorescence after 8 hours of incubation. Spore growth, as indicated by a color change produced by the pH indicator, was visually determined at 24, 48, and 168 hours of incubation.

The results are reported in Table 13.

Example 10

This example illustrates that biological

indicators of this invention, which include alpha-glucosidase immobilized by adsorption onto insoluble support materials, provide sterilization efficacy results comparable to conventional biological

indicators in AAMI sixteen towel test packs at 250°F (121°C) gravity exposures.

Preparation of Enzyme

Purified "alpha-glucosidase" (Lot #001) from

Bacillus stearothermophilus was obtained from Unitika LTD., Kyoto, Japan. Lyophilized alpha-glucosidase (10,000 units) with specific activity of 100 units/mg protein, was suspended in 1 ml of sterile distilled water. This suspension was dialyzed for 24 hours against 1 liter of sterile distilled water using a "Spectra/Por® Molecularporous Membrane", commercially available from Spectrum Medical Industries Inc.,

Los Angeles, CA, at a molecular weight cutoff of 3500 daltons. The dialyzed enzyme suspension was stored at 4°C until needed. Dilutions of dialyzed alpha-glucosidase were made in sterile distilled water to give a 50 ml suspension at an enzyme concentration of 200 units/ml.

Immobilization of Enzyme

Immobilization of the enzyme by adsorption onto the support materials "DEAE-Sephadex® A-50",

"CM-Sephadex® C-50", both commercially available from Pharmacia Fine Chemicals, Piscataway, NJ; "Silica Gel 60 Angstroms" commercially available from American Scientific Products, McGraw Park, IL; hydroxylapatite and calcium carbonate, both commercially available from EM Science, Cherry Hill, NJ, was accomplished by the following method.

The five support materials were equilibrated by suspension in appropriate buffer solutions as follows. DEAE-Sephadex, 0.5 g; silica gel, 1 g; hydroxylapatite, 1 g; and calcium carbonate, 1 g, were suspended into separate 100 ml solutions of 0.01 M potassium phosphate buffer, pH 7.3, and allowed to equilibrate for 2 days at ambient conditions. CM-Sephadex, 0.5 g, was

suspended into 100 ml of 0.01 M sodium acetate buffer, pH 4.6, and allowed to equilibrate for 2 days. The equilibrated support materials were then centrifuged at 7000 rpm, at 4°C, for 30 minutes, and the supernatant was discarded. The pellets of support materials were then resuspended by adding 10 ml of alpha-glucosidase solution, 200 units/ml, and mixing gently for 1 hour under ambient conditions using an orbital shaker.

The enzyme/support complex was pelleted by

centrifugation at 7000 rpm, at 4°C, for 15 minutes.

The supernatant was decanted and saved. The

enzyme/support complex was allowed to dry under ambient conditions for 4 days. The dried enzyme/support complex was stored at 4ºC until needed.

Measurement of the amount of alpha-glucosidase immobilized onto the five support materials was done by determining the amount of enzyme activity in units remaining in supernatant collected after immobilization of the alpha-glucosidase onto the support material as follows.

Nine hundred microliters of 20 mM p-nitrophenyl-alpha-D-glucopyranoside commercially available from

Sigma Chemical Co., St. Louis, MO, in sterile distilled water was mixed in a test tube with 100 microliters of a 1:100 dilution in distilled water of the supernatant. After 15 minutes at 30°C, 1000 microliters of 0.2 M sodium carbonate was added to the test tube to

terminate the enzyme-substrate reaction. The increase in absorbance at 400 nm due to the generation of substrate product, p-nitrophenol, was determined against controls from which the enzyme was omitted. A mole extinction coefficient of 18.1 cm² per micromole was used to calculate the amount of substrate product contained in the supernatant. One unit of enzyme activity is defined as the amount of alpha-glucosidase that forms 1 micromole of p-nitrophenol per minute at 30°C. The units of enzyme contained in the supernatant were subtracted from 2,000 units to yield the units of enzyme contained in the dried enzyme/support complex. The units of enzyme in the dried enzyme/support

products is reported in Table 14. Assembly of Devices

Devices were constructed as illustrated in FIGS. 3 and 4, and described in Example 1, except that 0.1 g of the dried enzyme/support product was placed in the outer container 40 prior to placing the barrier 47 within the outer container.

Three unit batches of the devices of the

invention, consisting of immobilized alpha-glucosidase, were placed in metal instrument trays. Three "Attest™ Biological Indicators 1262/1262P" and three "Attest™ Rapid Readout Biological Indicators 1291" commercially available from 3M, St. Paul, MN, were placed within AAMI steam test packs between the 8th and 9th towels from the bottom of the stack. The test packs were secured with autoclave tape.

The devices of the invention and the conventional AAMI biological test packs were exposed for 16, 18, and 20 minute intervals at 250ºF (132°C) gravity in an "Amsco Eagle™ Model 3000," steam sterilizer. Following exposure, the conventional biological indicators were removed from the AAMI sixteen towel test packs. The inner ampoules of the devices of the invention and the conventional biological indicators were crushed and the units were incubated at 60°C. An "Attest™ 190 Auto-Reader" was used to read alpha-glucosidase activity by measuring 4-methylumbelliferyl fluorescence after 4 and 8 hours of incubation. The results are reported in Table 15.

The data presented above demonstrates that the biological indicators of the invention, utilizing alpha-glucosidase immobilized by adsorption onto various water-insoluble support carriers can provide survival/kill results comparable with conventional biological indicators in AAMI test packs.

Example 11

This example illustrates the use of chemical immobilizer, D-Sorbitol, to enhance the survival/kill performance of the spore bound enzyme and spores when used with and without conventional test packs (as shown in FIGS. 5 & 6) in a European Sterilization Equipment Company prevacuum steam sterilization cycle (121°C).

Bacillus stearothermophilus spores were grown, coated on filter paper and immobilized with "D-Sorbitol," as described in Example 1. Biological indicators of this invention were constructed as illustrated in FIGS. 3 and 4 and as described in

Example 1.

Assembly of Test Packs

Test packs were constructed as shown in FIGURES 5 and 6. The test pack 100 comprised a box 102 having overall dimensions of 134 mm (5.36 in) by 140 mm (5.60 in) by 28 mm (1.12 in). The box was made of bleached sulfate paper unvarnished.

The box contained an open container 108 also made of bleached sulfate paper which was coated on its exterior surfaces with a steam impermeable

thermoplastic coating 110 of polypropylene laminate.

Container 108 was dimensioned to be only slightly smaller than the box 102.

Two stacks of sheets, 112 and 114, of semi-porous material separated by a stack of sheets 116 also of semi-porous material were contained in container 108.

Each stack of semi-porous material was formed of filter paper having an approximate basis weight of 214 pounds

(7 kg) per 3,000 square feet (280 m) and an approximate thickness of 1 mm per sheet. Stacks 112 and 114 included 36 sheets of filter paper. The semi-porous stack 116 was composed of 16 sheets of filter paper with a 13 mm by 49 mm area 118 cut from the center of each sheet in order to receive biological indicator 11 of this invention. The height of this central core, when assembled and dry, was approximately 10 mm.

The test pack was opened by opening the box flap 122, the top semi-porous sheets were removed and a conventional biological indicator or a biological indicator of this invention surrounded by a coiled metal spring 120, preferably made of stainless steel, was placed within the cavity in the center portion of the stack. The top sheets were then replaced and the box closed.

Comparative Test

The devices of the invention, used alone and in the above-described test packs, and controls consisting of conventional "Attest™ 1262 Biological Indicators" and "Attest™ 1291 Rapid Readout Biological Indicators" in the above-described test packs were placed in metal trays and exposed for 6, 6.5, 7, and 15 minute

intervals to a 121°C (250°F) prevacuum sterilization cycle, 3 negative pulses, in a gravity displacement and vacuum assisted sterilizer, commercially available as a "Getinge™ PACs 2000 High Vacuum Sterilizer", from

Getinge™ International, Inc., Lakewood, NJ. The settings on the sterilizer were as indicated in

Table 16. The cycle is a European Sterilization

Equipment Company prevacuum cycle. Following exposure, the biological indicators were evaluated as described in Example 1. The results are reported in Table 17.

The devices of this invention were designed to provide microbial challenge during exposure to steam sterilization cycles (including European sterilization cycles) which is equal to or greater than the microbial challenge provided by conventional test packs. The date reported in Table 17 demonstrates that the

biological indicators of this invention (with and without test packs) achieve and outperform this

requirement.

Example 12

Example 12 illustrates the use of chemical

immobilizer D-sorbitol to enhance the survival/kill performance of the spore bound enzyme and spore when used with and without conventional test packs (as shown in FIGS. 5 & 6) in a European Sterilization Equipment Company prevacuum steam sterilization cycle (134°C (272°F)).

The Bacillus stearothermophilus spores were coated on filter paper, dried, and immobilized as described in Example 1. Biological indicator devices were

constructed utilizing the immobilized spore strip as described in Example 1 and illustrated in Figures 3 and 4.

Three unit batches of the devices containing immobilized Bacillus stearothermophilus spores, used alone and in the test packs described in Example 13, and conventional "Attest™ 1262 Biological Indicators" and "Attest™ 1291 Rapid Readout Biological Indicators" in the conventional steam test packs described in

Example 13, were placed in metal instrument trays.

They were exposed for 0, 2, 4, 6, 8, 10, and 12 second intervals to a 134°C (272°F) prevacuum sterilization cycle, 3 negative pulses, 4 positive pulses in a gravity displacement and vacuum assisted sterilizer, commercially available as a "Getinge™ PACS 2000 High Vacuum Sterilizer", from Getinge International, Inc., Lakewood, NJ. The settings for the sterilizer were as indicated in Table 18. The cycle is a European Sterilization Company prevacuum cycle. Following exposure, the biological indicators were evaluated as described in Example 1. The results are reported in Table 19.

The data in Table 19 above demonstrates that the biological indicators of the invention utilizing spores and spore bound enzyme immobilized with D-sorbitol (with and without test packs) provide a greater

microbial challenge than do conventional biological indicators used in conventional steam sterilization test packs.

The following are trademarks :

"1278 Attest™ EO Pack"

"1276 Attest™ Steam Pack"

"Attest™ 1262/1262P Biological Indicator"

"Amsco Eagle™ Model 3000"

"Attest™ Biological Indicator"

"Attest™ 190 Auto-Reader"

"Attest™ 1276 Test Pack"

"API-XYM™ System"

"Attest™ 1264 Biological Indicator"

"Attest™ 1278 Test Pack"

"Attest™ Ethylene Oxide Biological Indicator 1264"

"Attest™ 1262 Biological Indicator"

"Getinge™ PACs 2000 High Vacuum Sterilizer"

"Getinge™ International , Inc. "

"Attest™ 1291 Biological Indicator"

"Sephadex® G-Types"

"Sepharose® Ion Exchanger"

"Sephadex® Ion Exchanger"

"Thinsulate® 200-B brand Thermal Insulation"

"Carbowax® PEG- 1450"

"Spectra/Por® Molecularporous Membrane"

"Percolle®"

"Sigma® Chemical Co. "

"GAF® Chem. Co . "

"DEAE - Sephadex® A-50"

"CM Sephadex® C-50"

Claims

CLAIMS :

1. A biological indicator comprising

(a) an outer container having liquid impermeable walls , said container having at least one opening therein;

(b) contained within said outer container a

detectable amount of

(1) a viable test microorganism useful to monitor a sterilization cycle or

(2 ) another source of an active test enzyme useful to monitor the sterilization cycle ,

which test microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized

microorganism or enzyme to survive or remain active following an exposure to the sterilization cycle which is sublethal to the test microorganism when contained in a test pack commonly used to monitor sterilization, and incapable of allowing any detectable amount of immobilized microorganism or enzyme to survive or remain active following an exposure to the sterilization cycle which is lethal to the test microorganisms when contained in the test pack commonly used to monitor

sterilization.

2. A test pack for determining the efficacy of a

sterilization cycle in a sterilization chamber comprising the biological indicator of claim 1 within a test pack material or device.

3 . A method of increasing the thermostability of

viable test microorganisms useful to monitor sterilization or active test enzymes useful to monitor sterilization within a biological

indicator comprising immobilizing at least 1×10² of the test microorganisms or at least 0.1 unit of the test enzyme within the indicator.

4. A method of increasing the thermostability of viable test microorganisms useful to monitor sterilization or active test enzymes useful to monitor sterilization within a biological

indicator comprising immobilizing the test

microorganism or test enzyme within the indicator to an extent capable of allowing a detectable amount of said immobilized microorganism or enzyme to survive or remain active following an exposure to the sterilization cycle which is sublethal to the test microorganism when contained in a test pack commonly used to monitor sterilization, and incapable of allowing any detectable amount of immobilized microorganism or enzyme to survive or remain active following an exposure to the

sterilization cycle which is lethal to the test microorganisms when contained in the test pack commonly used to monitor sterilization.

5. A method for determining the effectiveness of a sterilization cycle, comprising the steps of:

(a) subjecting to said sterilization cycle a

detectable amount of a test microorganism useful to monitor the sterilization cycle or test enzyme useful to monitor the

sterilization cycle, which test microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized microorganism or enzyme to survive or remain active following an exposure to the sterilization cycle which is sublethal to the test microorganism when contained in a test pack commonly used to monitor sterilization, and incapable of allowing any detectable amount of immobilized microorganism or enzyme to survive or remain active following an exposure to the sterilization cycle which is lethal to the test microorganisms when contained in the test pack commonly used to monitor

sterilization; (b) following the completion of the sterilization cycle, incubating

( 1) any viable immobilized test

microorganism with an aqueous nutrient medium capable of promoting growth of said viable immobilized microorganisms and a detector material capable of undergoing a detectable change in response to growth of the microorganisms ; or

(2 ) any active immobilized test enzyme with an effective amount of an enzyme

substrate capable of reacting with active enzyme to produce a detectable enzyme-modified product;

said incubation being for a time period and under conditions sufficient to promote growth of the microorganism or reaction of active enzyme with the enzyme substrate.

6. The biological indicator of claim 1 , or the test pack of claim 2 , or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4 , or the method for determining the effectiveness of a sterilization cycle of claim 5 , wherein the sterilization cycle is a steam cycle and the test microorganism or enzyme is

immobilized with an immobilizing agent selected from the group consisting of alditols ,

disaccharides , trisaccharides, and polymeric alcohols selected from the group consisting of polyvinyl alcohol , glycols and diols .

7. The biological indicator of claim 1, or the test pack of claim 2 , or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4 , or the method for determining the effectiveness of a sterilization cycle of claim 5 , wherein the sterilization cycle is an ethylene oxide cycle and the test microorganism or enzyme is immobilized with an immobilizing agent selected from the group consisting of alditols,

monosaccharides, polysaccharides, polylactams, and polymeric alcohols selected from the group

consisting of polyvinyl alcohol, glycols and diols.

8. The biological indicator of claim 1, or the test pack of claim 2, or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4, or the method of determining the effectiveness of a sterilization cycle of claim 5, wherein the test microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized

microorganism or enzyme to survive or remain active following exposure, outside the test pack material or device, to at least a 5 minute steam sterilization cycle of 121°C gravity, yet not capable of allowing any of said immobilized microorganism or enzyme to survive or remain active following an exposure, outside the test pack material or device, to said steam

sterilization cycle for up to 15 minutes.

9. The biological indicator of claim 1, or the test pack of claim 2, or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4, or the method of determining the effectiveness of a sterilization cycle of claim 5, wherein the test microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized

microorganism or enzyme to survive or remain active following exposure, outside the test pack material or device, to at least a 20 second steam sterilization cycle of 132°C prevacuum, yet not capable of allowing any of said immobilized microorganism or enzyme to survive or remain active following an exposure, outside the test pack material or device, to said steam

sterilization cycle for up to 6 minutes.

10. The biological indicator of claim 1, or the test pack of claim 2, or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4, or the method of determining the effectiveness of a sterilization cycle of claim 5, wherein the test microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized

microorganism or enzyme to survive or remain active following exposure, outside the test pack material or device, to at least a 5 second steam sterilization cycle of 121°C or 134°C prevacuum, yet not capable of allowing any of said

immobilized microorganism or enzyme to survive or remain active following an exposure, outside the test pack material or device, to said steam sterilization cycle for up to 2 minutes.

11. The biological indicator of claim 1, or the test pack of claim 2, or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4, or the method of determining the effectiveness of a sterilization cycle of claim 5, wherein the test microorganism or enzyme has been immobilized to an extent capable of allowing a detectable amount of said immobilized

microorganism or enzyme to survive or remain active following exposure, outside the test pack material or device, to at least a 15 minute ethylene oxide sterilization cycle, yet not capable of allowing any of said immobilized microorganism or enzyme to survive or remain active following an exposure, outside the test pack material or device, to said ethylene oxide sterilization cycle for up to 90 minutes.

12. The biological indicator of claim 1, or the test pack of claim 2, or the method of increasing the thermostability of microorganisms or enzymes of claims 3 or 4, or the method of determining the effectiveness of a sterilization cycle of claim 5, wherein the test microorganism or enzyme is immobilized by

( 1) adsorption onto a water-insoluble support material ;

(2 ) reaction with a water-insoluble support material capable of forming covalent or ionic bonds to the test microorganism or test enzyme ;

(3 ) entrapping the microorganism or enzyme within a crosslinked polymer gel matrix comprising non-ionic polymer-forming materials which are non-reactive with the microorganism or enzyme;

(4 ) reaction with a crosslinking agent capable of forming intra- or inter-molecular cross links between the test microorganisms or test enzyme;

(5) microencapsulating the test

microorganism or enzyme;

or any combination thereof .